Roles of a membrane-localized beta subunit in the formation and targeting of functional L-type Ca2+ channels

Identification and subcellular localization of the subunits of L-type calcium channels and adenylyl cyclase in cardiac myocytes

The properties of cardiac L-type channels have been well characterized electrophysiologically, and many such studies have demonstrated that the channels are regulated by a cAMP-dependent pathway. However, the subunit composition of native cardiac L-type calcium channels has not been completely defined. Furthermore, a very important question exists regarding the status of the C-terminal domain of the pore-forming alpha1 subunit, as this domain has the potential to be the target of protein kinases but may be truncated as a result of post-translational processing. In the present studies, the alpha1C and beta2 subunits were identified by subunit-specific antibodies after partial purification from heart membranes, or immunoprecipitation from cardiac myocytes. Both the beta2 and the full-length alpha1C subunits were found to be expressed and co-localized in intact cardiac myocytes along T-tubule membranes. Using a quantitative antibody binding analysis, we demonstrated that the majority of the alpha1C subunits in intact cardiac myocytes appear to be full-length. In addition, we observed that adenylyl cyclase is localized in a pattern similar to the channel subunits in cardiac myocytes. Taken together, our results provide new insights into the structural basis for understanding the regulation of L-type calcium channels by a cAMP-mediated signaling pathway.

Recovery of Ca2+ current, charge movements, and Ca2+ transients in myotubes deficient in dihydropyridine receptor beta 1 subunit transfected with beta 1 cDNA

The Ca2+ currents, charge movements, and intracellular Ca2+ transients of mouse dihydropyridine receptor (DHPR) beta 1-null myotubes expressing a mouse DHPR beta 1 cDNA have been characterized. In beta 1-null myotubes maintained in culture for 10-15 days, the density of the L-type current was approximately 7-fold lower than in normal cells of the same age (Imax was 0.65 +/- 0.05 pA/pF in mutant versus 4.5 +/- 0.8 pA/pF in normal), activation of the L-type current was significantly faster (tau activation at +40 mV was 28 +/- 7 ms in mutant versus 57 +/- 8 ms in normal), charge movements were approximately 2.5-fold lower (Qmax was 2.5 +/- 0.2 nC/microF in mutant versus 6.3 +/- 0.7 nC/microF in normal), Ca2+ transients were not elicited by depolarization, and spontaneous or evoked contractions were absent. Transfection of beta 1-null cells by lipofection with beta 1 cDNA reestablished spontaneous or evoked contractions in approximately 10% of cells after 6 days and approximately 30% of cells after 13 days. In contracting beta 1-transfected myotubes there was a complete recovery of the L-type current density (Imax was 4 +/- 0.9 pA/pF), the kinetics of activation (tau activation at +40 mV was 64 +/- 5 ms), the magnitude of charge movements (Qmax was 6.7 +/- 0.4 nC/microF), and the amplitude and voltage dependence of Ca2+ transients evoked by depolarizations. Ca2+ transients of transfected cells were unaltered by the removal of external Ca2+ or by the block of the L-type Ca2+ current, demonstrating that a skeletal-type excitation-contraction coupling was restored. The recovery of the normal skeletal muscle phenotype in beta 1-transfected beta-null myotubes shows that the beta 1 subunit is essential for the functional expression of the DHPR complex.

cAMP-dependent regulation of cardiac L-type Ca2+ channels requires membrane targeting of PKA and phosphorylation of channel subunits

The cardiac L-type Ca2+ channel is a textbook example of an ion channel regulated by protein phosphorylation; however, the molecular events that underlie its regulation remain unknown. Here, we report that in transiently transfected HEK293 cells expressing L-type channels, elevations in cAMP resulted in phosphorylation of the alpha1C and beta2a channel subunits and increases in channel activity. Channel phosphorylation and regulation were facilitated by submembrane targeting of protein kinase A (PKA), through association with an A-kinase anchoring protein called AKAP79. In transfected cells expressing a mutant AKAP79 that is unable to bind PKA, phosphorylation of the alpha1C subunit and regulation of channel activity were not observed. Furthermore, we have demonstrated that the association of an AKAP with PKA was required for beta-adrenergic receptor-mediated regulation of L-type channels in native cardiac myocytes, illustrating that the events observed in the heterologous expression system reflect those occurring in the native system. Mutation of Ser1928 to alanine in the C-terminus of the alpha1C subunit resulted in a complete loss of cAMP-mediated phosphorylation and a loss of channel regulation. Thus, the PKA-mediated regulation of L-type Ca2+ channels is critically dependent on a functional AKAP and phosphorylation of the alpha1C subunit at Ser1928.

Ion-dependent inactivation of barium current through L-type calcium channels

It is widely believed that Ba2+ currents carried through L-type Ca2+ channels inactivate by a voltage-dependent mechanism similar to that described for other voltage-dependent channels. Studying ionic and gating currents of rabbit cardiac Ca2+ channels expressed in different subunit combinations in tsA201 cells, we found a phase of Ba2+ current decay with characteristics of ion-dependent inactivation. Upon a long duration (20 s) depolarizing pulse, IBa decayed as the sum of two exponentials. The slow phase (tau approximately 6 s, 21 degrees C) was parallel to a reduction of gating charge mobile at positive voltages, which was determined in the same cells. The fast phase of current decay (tau approximately 600 ms), involving about 50% of total decay, was not accompanied by decrease of gating currents. Its amplitude depended on voltage with a characteristic U-shape, reflecting reduction of inactivation at positive voltages. When Na+ was used as the charge carrier, decay of ionic current followed a single exponential, of rate similar to that of the slow decay of Ba2+ current. The reduction of Ba2+ current during a depolarizing pulse was not due to changes in the concentration gradients driving ion movement, because Ba2+ entry during the pulse did not change the reversal potential for Ba2+. A simple model of Ca(2+) -dependent inactivation (Shirokov, R., R. Levis, N. Shirokova, and F., Ríos. 1993. J. Gen. Physiol. 102:1005-1030) robustly accounts for fast Ba2+ current decay assuming the affinity of the inactivation site on the alpha 1 subunit to be 100 times lower for Ba2+ than Ca2+.

Importance of the different beta subunits in the membrane expression of the alpha1A and alpha2 calcium channel subunits: studies using a depolarization-sensitive alpha1A antibody

The plasma membrane expression of the rat brain calcium channel subunits alpha1A, alpha2-delta and the beta subunits beta1b, beta2a, beta3b and beta4 was examined by transient expression in COS-7 cells. Neither alpha1A nor alpha2-delta localized to the plasma membrane, either alone or when coexpressed. However, coexpression of alpha1A or alpha2-delta/alpha1A with any of the beta subunits caused alpha1A and alpha2 to be targetted to the plasma membrane. The alpha1A antibody is directed against an exofacial epitope at the mouth of the pore, which is not exposed unless cells are depolarized, both for native alpha1A channels in dorsal root ganglion neurons and for alpha1A expressed with a beta subunit. This subsidiary result provides evidence that either channel opening or inactivation causes a conformational change at the mouth of the pore of alpha1A. Immunostaining for alpha1A was obtained in depolarized non-permeabilized cells, indicating correct orientation in the membrane only when it was coexpressed with a beta subunit. In contrast, beta1b and beta2a were associated with the plasma membrane when expressed alone. However, this is not a prerequisite to target alpha1A to the membrane since beta3 and beta4 alone showed no differential localization, but did direct the translocation of alpha1A to the plasma membrane, suggesting a chaperone role for the beta subunits.

Expression and subunit interaction of voltage-dependent Ca2+ channels in PC12 cells

Nerve growth factor (NGF)-induced differentiation in PC12 cells is accompanied by changes in the expression of voltage-dependent Ca2+ channels. Ca2+ channels are multimeric complexes composed of at least three subunits (alpha1, beta, and alpha2delta) and are involved in neuronal migration, gene expression, and neurotransmitter release. Although attempts have been undertaken to elucidate NGF regulation of Ca2+ channel expression, the changes in subunit composition of these channels during differentiation still remain uncertain. In the present study, patch-clamp recordings show that in addition to the previously documented L-type and N-type Ca2+ currents, undifferentiated PC12 cells also express an omega-agatoxin-IVA-sensitive (P/Q-type) component. In addition, the corresponding mRNA encoding the pore-forming alpha1 subunits for these channels (C, B, and A, respectively) was detected. Likewise, mRNA for three distinct auxiliary beta subunits (1, 2, 3) were also found, beta3 protein being dominantly expressed. Immunoprecipitation experiments show that the N-type Ca2+ channel is associated with either a beta2 or beta3 subunit and that NGF increases the channel expression without affecting its beta subunit association. These results (1) indicate that the diversity of Ca2+ currents in PC12 cells arise from the expression of three distinct alpha1 and three different beta subunit genes; (2) support a model for heterogenous beta subunit association of the N-type Ca2+ channel in a single cell type; and (3) suggest that the regulation of the N-type Ca2+ channel during NGF-mediated differentiation involves an increase in the number of functional channels with no apparent changes in subunit composition.

Basic fibroblast growth factor increases functional L-type Ca2+ channels in fetal rat hippocampal neurons: implications for neurite morphogenesis in vitro

Basic fibroblast growth factor (bFGF) is a potent neurotrophic factor that regulates cell proliferation and differentiation during neuronal development. Here we report that fetal hippocampal neurons chronically treated with bFGF displayed larger [Ca2+]i increases than nontreated neurons in response to high K(+)-induced depolarization. This [Ca2+]i response was abolished by nicardipine and was little affected by treatments that depleted intracellular Ca2+ stores, thus reflecting the activities of L-type voltage-dependent Ca2+ channels. Whole-cell recordings also demonstrated increased high-voltage-activated Ca2+ currents in bFGF-treated neurons, whereas low-voltage-activated Ca2+ currents remained unchanged. bFGF-stimulated increase in Ca2+ response was not observed in neurons treated with cycloheximide or actinomycin D, indicating that protein and RNA synthesis were required for this effect. Visualization using a fluorescent dihydropyridine analog revealed that bFGF-treated neurons expressed increased amounts of L-type Ca2+ channels on the cell body. In addition, bFGF-treated neurons acquired distinctive morphology of neurites that was characterized by markedly increased neuritic branching. The branching points in neurites were associated with clusters of L-type Ca2+ channels and resultant "Ca2+ hotspots" that showed large [Ca2+]i increases in response to membrane depolarization. Concurrent application of nicardipine completely blocked the bFGF-stimulated increase in neuritic branching. Therefore, bFGF enhances the expression of functional L-type Ca2+ channels on the cell body and neurites of fetal hippocampal neurons, which may play an important role in the regulation of their differentiation and the establishment of their neurite morphology.

Absence of the beta subunit (cchb1) of the skeletal muscle dihydropyridine receptor alters expression of the alpha 1 subunit and eliminates excitation-contraction coupling

The multisubunit (alpha 1s, alpha 2/delta, beta 1, and gamma) skeletal muscle dihydropyridine receptor transduces transverse tubule membrane depolarization into release of Ca2+ from the sarcoplasmic reticulum, and also acts as an L-type Ca2+ channel. The alpha 1s subunit contains the voltage sensor and channel pore, the kinetics of which are modified by the other subunits. To determine the role of the beta 1 subunit in channel activity and excitation-contraction coupling we have used gene targeting to inactivate the beta 1 gene. beta 1-null mice die at birth from asphyxia. Electrical stimulation of beta 1-null muscle fails to induce twitches, however, contractures are induced by caffeine. In isolated beta 1-null myotubes, action potentials are normal, but fail to elicit a Ca2+ transient. L-type Ca2+ current is decreased 10- to 20-fold in the beta 1-null cells compared with littermate controls. Immunohistochemistry of cultured myotubes shows that not only is the beta 1 subunit absent, but the amount of alpha 1s in the membrane also is undetectable. In contrast, the beta 1 subunit is localized appropriately in dysgenic, mdg/mdg, (alpha 1s-null) cells. Therefore, the beta 1 subunit may not only play an important role in the transport/insertion of the alpha 1s subunit into the membrane, but may be vital for the targeting of the muscle dihydropyridine receptor complex to the transverse tubule/sarcoplasmic reticulum junction.

Tissue-specific expression of splice variants of the mouse voltage-gated calcium channel alpha2/delta subunit

Five different splice variants of mouse alpha2/delta subunit isoforms (alpha2a-e), which arose from various combinations of three alternatively spliced regions, were cloned with a combination of cDNA library screening and RT-PCR. Expression patterns and relative abundance of the various isoforms in mouse tissues were determined with an RNAse protection assay. Skeletal muscle and brain expressed single isoforms, alpha2a and alpha2b, respectively; however, the cardiovascular system expressed all five isoforms. Heart expressed mainly isoforms alpha2c and alpha2d while, in contrast to other species, aorta expressed predominantly alpha2a, the 'skeletal muscle' isoform. Smooth muscle-containing tissues expressed alpha2d and alpha2e. Thus, alpha2/delta isoforms are restricted in their tissue expression, suggesting an important functional role for the differentially spliced variants.

Identification of palmitoylation sites within the L-type calcium channel beta2a subunit and effects on channel function

The hydrophilic beta2a subunit of the L-type calcium channel was recently shown to be a membrane-localized, post-translationally modified protein (Chien, A. J., Zhao, X. L., Shirokov, R. E., Puri, T. S., Chang, C. F., Sun, D. D., Rios, E., and Hosey, M. M. (1995) J. Biol. Chem. 270, 30036-30044). In this study, we demonstrate that the rat beta2a subunit was palmitoylated through a hydroxylamine-sensitive thioester linkage. Palmitoylation required a pair of cysteines in the N terminus, Cys3 and Cys4; mutation of these residues to serines resulted in mutant beta2a subunits that were unable to incorporate palmitic acid. Interestingly, a palmitoylation-deficient beta2a mutant still localized to membrane particulate fractions and was still able to target functional channel complexes to the plasma membrane similar to wild-type beta2a. However, channels formed with a palmitoylation-deficient beta2a subunit exhibited a dramatic decrease in ionic current per channel, indicating that although mutations eliminating palmitoylation did not affect channel targeting by the beta2a subunit, they were important determinants of channel modulation by the beta2a subunit. Three other known beta subunits that were analyzed were not palmitoylated, suggesting that palmitoylation could provide a basis for the regulation of L-type channels through modification of a specific beta isoform.

A potential site of functional modulation by protein kinase A in the cardiac Ca2+ channel alpha 1C subunit

The well-characterized enhancement of the cardiac Ca2+ L-type current by protein kinase A (PKA) is not observed when the corresponding channel is expressed in Xenopus oocytes, possibly because it is fully phosphorylated in the basal state. However, the activity of the expressed channel is reduced by PKA inhibitors. Using this paradigm as an assay to search for PKA sites relevant to channel modulation, we have found that mutation of serine 1928 of the alpha 1C subunit to alanine abolishes the modulation of the expressed channel by PKA inhibitors. This effect was independent of the presence of the beta subunit. Phosphorylation of serine 1928 of alpha 1C may mediate the modulatory effect of PKA on the cardiac voltage-dependent ca2+ channel.

Enhancement of ionic current and charge movement by coexpression of calcium channel beta 1A subunit with alpha 1C subunit in a human embryonic kidney cell line

1. Coexpression of the beta subunit with the alpha 1C subunit of the cardiac L-type Ca2+ channel has been shown to increase ionic current. To examine the mechanism of this increase, ionic and gating currents were measured in transiently transfected HEK293 cells. 2. Beta 1A subunit coexpression increased the maximal whole-cell conductance (Gmax) measured in 10 mM Ba2+ from 91 +/- 11 to 833 +/- 107 pS pF-1 without a change in the voltage dependence of activation (V1/2: -6.1 +/- 1.1 and -6.6 +/- 0.9 mV, respectively). 3. Gating currents were smaller in cells expressing only the alpha 1C subunit (only four out of eleven cells exhibited gating currents above the limits of detection, whereas eight out of eight beta 1A coexpressing cells had measurable gating currents). The gating currents were integrated to measure the intramembrane charge movement (Q). The ON charge movement (Qon) could be described by a Boltzmann distribution reaching a maximal value of Qon,max. 4. The mean ratio of Gmax: Qon,max increased from 99 +/- 6 to 243 +/- 30 pS fC-1 with beta 1A coexpression, demonstrating that the beta 1A subunit changes the gating of alpha 1C channels to favour the opening of the channels. However, this 2.5-fold change in the Gmax: Qon,max ratio explains less than half of the 9.2-fold increase in Gmax with beta 1A subunit coexpression. The major effect is due to a 3.7-fold increase in Qon,max, demonstrating that beta 1A subunit coexpression increases the number of functional surface membrane channels.